Lubrication method and means



0a. 1s, 1932. Q u, ZERK 1,883,277

LUBRICATION METHOD AND MEANS Filed Oct. 7, 1929 5 Sheets-Sheet 1 oa. 1s, 193.2.-A o, U, ZERK 1,883,277

LUBRICATION METHOD AND MEANS Filed oct. 7, 192s 5 sheets-sheet 2 Oct. 18, 1932-A Q, U ZERK 1,883,277

` LUBRICATION uETHoD AND MEANS Filed Oct. 7, 1929 5 Sheets-Sheet' 3 v m www Oct.l8, 1932.ro. u. zERK LUBRICATIN METHOD AND MEANS 5 Sheets-Sheet 5 Filed Oct. 7. 1929 SCarZ/.Zefja Cua/t@ Patented Oct. 1.8, 1932 y UNrraof s'rrvras PATENT OFFICE OsCAR U. ZERR, or CHICAGO, ILLINOIS, AssIGNOR To` ALEMITE CORPORATION, or

CHICAGO, ILLINOIS, A CORPORATION or DELAWARE f LURRICA'TION mEmIIOD AND MEANS Application filed October 7, 1929. Serial 179.398,065;

My invention relates to the art of lubrication and is more particularly concerned with the lubrication of certain classes of bearings which are adapted to employ lubricant of heavy body, such as grease or high viscosity Oil.

In general, such bearings are not high speed bearings, that is rotate under 2000 It. P. M. and `in many cases have a rocking or partial turning movement only.d

I shall herein show, by way of illustration but not of limitation, my presentA invention as applied to certain chassis bearings of an automobile to `which the invention is well adapted.

is adaptable equally well to automotive work, more particularly to the lubrication of the chassis of vehicles, such as autmobiles, trartors,vgun carriages,war tanks, locomotives, airplanes, etc., or to industrial'lubrication,

that is to the lubrication of stationary ma-f chinery, such as stamping presses, printing presses, textile machinery, shafting, and others of the numerous types of machines and machinel tools of modern industry. j

The present invention is furthermore par# ticularly useful for the lubrication ofbearings which have heretofore been lubricated intermittently, that is, where lubricant is periodically injected into them, butrthe' in vention is not to be restricted to that particular use as the bearings and lubricating method of my invention provide certain ad-y vantages for continuous lubrication,^partic ularly of the non-circulating type.,

The desired object in the lubrication of a bearing is to keep the metal surfaces which move with respect to each other from engaging directly by maintaining between them a film of lubricant. Any solid or nonlubricating particles which enter the beam' ings tend' to defeat the purpose of the lubricant by forming a solid bridge between the two bearing surfaces. l

vIn bearings employing grease, particularly -in automotive Work, dirt and grit are often contained in the grease. The same is true to a certain extent where heavy oil is employed. In addition, metal particles become detached 'the desired film of lubricant. It is to be understood that the invention from the surfaces and defeat to a certain extent the lilm oflubricant. Also, in bearings exposed to dirt and dust, as for example the chassis bearings in a vehicle,.non-lubricating particles tend to becomel deposited between 55 the bearing surfaces.

Grease also tends to leave a deposit of soap whichJ is undesirable and particularly so,"if it embeds grit, scale or other solid particles.' The chief object of ,the present invention 1s to provide a no-vel bearing and method of lubrication` which shall maintain the bearing surfaces substatially'free of non-lubrieating material and properly supplied with ci. The accepted practice heretofore has been to provide a substantially closed chamber or pocket in communication with the bearing Y surfaces and into this pocket to force periodically charges of ygrease'or heavy Oil. N o` structural provision is `made for the removal of grit, metal particles, etc. from the bearings. Such non-lubricating particles ,are deposited either in a part of the bearings orl in said closed chamber or pocket. l

If the particles are deposited in the bearings, they tend to freeze up the bearings. If they are deposited inthe chamber or pocket, by working of the bearing they are then forced agaln into the bearings by the next 8L operation of injected lubricant into the pocket.

According to my invention, the chamber or pocket is dispensed with and an open passageway provided instead. This passageway communicates with an inlet which may be of known or any desired form extending to' a suitable point outside the bearings surfaces. Thisl open passageway functions in the following capacities. y

1. To serve as a supply chamber for lubricant which, by the motion of the bearing surfaces, is carried between them in the form of a lubricating ilm. l

2. To serve as a repository for non-lubri- 95 l eating particles which, by the motion of the troduce the lubricant by low pressure only. This advantage is so important that it tends to overshadow the main purpose of the invention.

It makes possible the use of simpler and less expensive lubricant compressors, guns or pumps, the latter used in centralized lubrication. It renders the operation of a gun or ing and structural advantages Ipump much simpler and more expeditious.

For example, when a hand gun of the screw operated plunger typeis employed, less time 'and energy are required to discharge the required quantity o'flubricant. Compression y o1' decompression, which was formerly nec# essary to uncouple the coupling members of a -highpressure grease gun, 1s not required` when a low pressure gun is used and consequently less wastage due to leakage of lubricant occurs. The tightness of the fit between arts is not so important and particularly the t of the nozzle and nipple in lubricating apparatus of the 'contact type may be much more readily maintained because of greatly decreased pressure. Y a 2. S

There are numerous other advantages ,of the invention which will become more apparent from the following detaileddescription. I show in detail herein the shackle bearings of an automobide as in them the advantages of the invention become readily apparent. In this connection I may point out that the invention facilitatesthe manufacture of such bearings and provides certain manufacturnot heretofore possible.

I shall now outline briefly how, in the specifically described form of bearings, I secure the desired result of a self-cleaning, lowpressure hearing.

In bearlngs used for chassis lubxiication of automobiles which are subjected to" shocks y and sudden heavy loads, a small substan- 655l the presence of a. closed'groove or pocket tially crescent shaped space is formed between the bearing'and itsv bushing. It is "of course desirable to keep the bearing tight so that rattling or motion of the bearing in its bushing is prevented. While the thickness of the substantiall crescent shaped clearance 5" 1 space, above re erred to, varies in practice very often this thickness at its greatest dimension is about .003 of an inch, while near the two ends of the clearance, viewing the same in cross-section through the bearing, it

f may be less than .0001 of an inch and graduf c ally tapers to zero at the point where the bushing and bearing are support the load.

In such hearings as previously constructed,

in engagement to provides no yrelief except at the widest part of the clearancefor grit, scale, metal particles and the soap whichis the result of the separation of the oil from the grease.

It is well known that the pounding and churning action upon grease due to the vibraltion of the hearing 1n its shackle jor vice versa, tends vto separate the oil out of the grease leaving a deposit of soap which, with the grit metal articles and the like, tends to form a hard eposit, not only in the closed end groove, but also in the clearance of the' hearing and bushing which has no other outlet, the bearingtending to become frozen and the holt and bushing resisting movement relative'to eachother. l

It has been attempted, according to the prior art, toremedy this condition by forcingl grease or oil into the bearing under high pressure or exceedingly high pressure, often termed, super-pressure or booster-pressure.I When" such oil or fresh grease has been forced into the bearing and has penetrated more or less of the frozen portion between the bolt and bushing, for example, it usually follows only one very narrow channel in the deepest part of the crescent shaped clearance between the parts. When the bearparts are again relatively movable, it

v has enerally been thought heretofore that the caring is then properly lubricated. This, however, is not the case because the filled tapered side portions of the crescent shaped spaceadjoining the widest portion of the clearancewhich have been opened by the fresh lubricant forced .through the same at super-pressure still remain charged with non-lubricating particles and in a relatively short time the bearing again becomes frozen.

The cross hole or inlet duct in the bolt or bushing may become clogged with solid material and the same can be opened only .by the application of super-pressure which forces such additional solid material into the bearing itself. Bearings are often constructed with a circular groove in the bolt registering with the crosshole in the bolt or other entering duct for lubricant, but this doesnot materially alter the case, since such a circular groove extends only along a short part of the length of the bearing and assuch circular groove has an outlet onlyl in the longitudinal groove in the holt or in the bushing,--providing a longitudinal groove is used in addition to a circular groove,-the circular groove itself become a depository for solid particles and gradually iills up and becomes useless. The tendency therefore is the same to accumulate solid particles which gradually tend to freeze up the bearing.

It has been very strongly advertised and therefore is often believed that high-pressure lubrication forces out' all of the old grease from a bearing and replaces the same with new clean grease all over the bearing surfaces. In fact, it has heretofore been thought that only high-pressure'lubrication would give the desired result of supplying the bearing with the proper film of lubricant. As high-pressurel has failed to produce this result, super-pressure has been introduced but has failed to get the desired results.

`narrow parts of the clearance regardless of the pressure employed, results in a more detinite forcing or wedging'of the'solid or nonlubricating particles into such narrow space and in that respect tends all the more to compact in such narrow clearance space the nonlubricating particles. Any new grease which is forced into thebearing at high pressure will move-in a relatively narrow channel at the widest 4portion of the crescent shaped play, naturally choosing the path of least resistance Aand failing to clean out along the sides where the narrow clearance exists, the `map, grit, metal particles and the like which are merely more firmly lodged in such position.. v

Furthermore, the use of high or superpressure has a direct influence upon all of the parts of the lubricant guns and lubricant receiving nipples and the like, especially in the construction of the couplings where the grease gun is temporarily rigidly `connected to the lubricant receiving nipple.

These couplings are apt to leak consider-I ably 'under high pressure when grit which is deposited onA all nipples of an e posed mavchine, such as' an automobile bearing, is not thoroughly cleaned off before applying the grease gun nozzle, and 1t 1s substantially liever cleaned oli the nipple; eitherl by the owner of the vehicle nor at the service stations. l

The presence of such grit upon the nipple which remains between the nipple and the coupling, causes leakage which makes it necessary toA use many times more grease in'lu- `oricating a bearing with a high pressure grease gun than the bearing actually needs, withthe res-ult that the cost of grease used is many times higher than necessary and the escape of the grease at the couplings and nipples isv messy and undesirable. With my system, not only is proper lubrication secured, grit, soap, and 'non-lubricating particles being easily and readily carried out of the bearing, but this is performed at unusually low pressure, that is pressures at from 10 to 25 lbs. per square inch. Also, far less grease or none at all, leaks around the coupling members even with the presence of grit upon the external surface of the nipple or the like.

While the chief object of the invention as above statedv yis. to secure proper lubrication, it is an equally important object of the present invention to secure the same by the use of low pressure only.

Another object of the invention is to provide an improved bearing construction vwhich makes the above method of operation possible. l

Another object of the invention is to secure a selective filtering action in a bearing lubricated by lubricant containinggritor other non-lubricating impurities so as to permit the lubricant to pass between the bearing surfaces, but to retain or hold back the impurities and discharge them out of the bearings at each succeeding injection of fresh lubricant, or in other words it is my object to f orce impurities of the lubricant out of the bearing instead of into the bearing.

A further object of the invention is t provide suitable structures which will carry out the above in a simple and eective manner.

Another object of my, invention is to provide the combination witlra bearing having the aforesaid-advantages and from which resistance to the introduction of grease has been lsubstantially eliminated, of suitable means for receiving any kind of lubricating apparatus or system. l

Another object of the invention is to provide a bearing struct-ure which can be properly lubricated by relatively low pressure and which eliminates the necessity for any such high pressure as are now considered necessary to properly lubricate bearings.

Another object of my invention is to havea longitudinal channel or channels in the bearings or in the bushings extend from the cresshole in the bearings or a crosshole inthe bushings and through which the lubricant is fed, to Aat least one end of the bearing to discharge at a point at or near the ends of4 the bearing surfaces. e

Another object of my invention is to have in one form of the invention, the groove of my invention -extended radially from the cylindrical portion to afford an outlet through a radial passageway formed in one of the members or disposed along a radial bearing surface.

Another object of the invention is to form l the groove of my invention in two sections, namely, a groove lin one of the cylindrical parts of the bearing and a communicating groove or passageway along/the radial face of the bearing and further to keep these two sccploy these grooves or any part of them, Ior eX- tensions of them, as means for scraping fr om v the bearing surfaces, or any part of them,

non-lubricating particles or accumulated impurities, particularly where a highly viscous lubricant is employed.'

Another object of my invention is to provide in a bearing a lubricant reservoirin the form of a channel or channels extending from end to end of the bearing, or otherwise substantially throughout the bearing, such reservoirs being in constant free communication with the bearing surfaces.

Another object of the invention is to provide in a bearing of the above type, a split bushing made of sheet metal bent to shape.

Another object of my invention is to provide bushings either of solid tubing or of formed sheet metal in which the grooves or channels are formed by broaching, stamping, pressing or drawing.

A further object of'my invention is to embody the method and means above described in a shackle bolt bearing for vehicles.

Other and further objects will become apparent from the following description and/ the appended claims.

Now in order to acquaint those skilled in the art with the manner of constructing and l operating a device embodying my inventlon,l

I shall describe in connection with the accompanying drawings, a specific embodiment of i `my invention and its mode of use.

In the drawings, Figure 1 .is a diagrammatic showing of two bearing parts, illustrated in section;

Figure 2 is a perspective viewvof the lower bearing part, shown in Figure 1;

Figure 3 is a view similar to Figure 1, illustrating the action of the bearingrsurfaces when grit or non-lubricating particles become deposited between the bearing surfaces Figure 4 is a view like Figure 3 showing the non-lubricating particles scraped off at the end surfaces and into the central groove;

Figure 5 is a view similar to Figure 3, showing the non-lubricating particles introduced between thebearing surfaces by the injection of fresh lubricant;

Figure Gis a vertical section through a pair I cf shackle bearings connected by shackle links, the upper bearing illustrating the mode of operation of the present invention and the lower bearing illustrating the construction and mode of operation of known type of bearings.

` Figure 7 is a sectional I viewtaken onthe line 7-7 of Figure 6;

Figure 8 is a similar view taken through a bearing lin which the pin has a crossan automobile;

Figure 11 is a section taken on the line 11-11 of Figure 10;

Figure 12 is a section similar to Figure v10 showing another embodiment of the present invention in connection with another form of shackle connection between the frame and spring of an automobile; 4

Figure 18 is an end elevation of the shackle connection shown in Figure 12 partially in section the View being taken generally on line ?13 of .Figure 12;

Figure 14 is a transverse section taken on the line 14-14 of -Figure 12;

Figure 15 is a transversesection taken on the line 15-15 of Figure 12;

Figure 16 is a fragmentary section similar to Figure 10y showing another embodilnent of the invention;

Figure 17 is a transverse section taken on the line 17-17 of Figure 16;

Figure '18 is'a fragmentary section similar to Figure 16 showing another embodiment;

Figure 19 is a transverse section taken on the line 19-19 of Figure 18;

Figure `20 is .a fragmentary section similar to Figures 16 and 18 and showing another embodiment of the invention; s

Figure 21 is a transverse section taken on the line 21-.21 of Figure 20;

Figure 22 is a fragmentary section similar to Figure lOshowing an embodiment of the invention in connection with another form of shackle connection;

Figure 23 is a transverse section taken on the yline 23-23 of Figure 22;

Figure 24 is a transverse section taken on theqline 24-24 of Figure 22;

Figure 25 is a longitudinal axial sectional view of a grease or oil gun forming a source of lubricant supply,and particularly a low` pressure source of lubricant supply for the present invention; y

Figure 26 is an elevational View of the gun shown in Figure 25;v

Figure 27 is a longitudinal section through another form of bearing nipple for use with the present invention;

Figure 28 is a diagrammatic cross-section showing the crescent shaped play between the journal and bearing parts of a bearing and illustrating the movement of new grease in a bearing of the prior art supplied with RII Figure 10.

lubricant at uhigh'or super-pressure; and Figure 29 is a section online 29-29 of Referring now to Figure 1 I have shown therein two bearing members A, -B having by a mechanism, such as E. The member B has an inlet passageway Ffor the introduction of lubricant between the surfaces C and D. yThe horizontal passageway F communicates by wa o f a vertical passageway G with a groove yformed in the member B, opening into the plane bearing surface D.

' Greasewhich is forced into the passageway F will reach its place between `the bearing' surfaces by way of the vertical passageway G and through the distributing grooveH.

-- .It is to be observed that the groove H is clearly a distributing groove and its function is to distribute lubricant over a wider area than could be done by the mere ending of the vertical passageway G at the surface.

The groove H stops short of the slide edges of the bearing surface D, solid portions of the bearing remaining at I and J. Now assume that the parts shown in Figures 1 and 2 are supplied with grease or heavy oil containing grit, or th'at `metal particlesldetach themselves from the bearing surfaces, or that grit otherwise comes "between the bearing surfaces C and D, such particles shown, for example, at KKK.- These non-lubricating particles K form solid bridges or struts between the bearing surfaces defeating the action of the film of lubricant L to alarge extent. In addition, they -tend to cut and abrade the bearing surfaces and their presence in the bearing is, as is well known to the art, undesirable. Assume that to the working of the bearings, that is by movement of the surfaces C--D relative to each other, these non-lubricating particles ICK are gradually eliminated, as by scraping off at the ends and as by being scraped off in the distributing groove H. AThe action of the bearing immediately improves las soon as such non-lubricating particles are eliminated from between the bearingfsurfaces. But upon the next injection of lubricant, as illustrated in Figure 5, these same particles which were deposited in the distribution groove, are again introduced between the bearing surfaces'C and D and the trouble which they cause starts again. 1 y

Now while I have shown in thefdiagrams of Figures 1 to `5, plane surfaces for the bearings and .while these have -a tendency to eject or wipe oif or scrape the non-lubricats ing particles away from the ends of the bearings, .when two cylindricalsurfaces are in contact for rocking or rotative motion, such escape is not possible and the grit will stay in the bearing.

As illustrative of this, I refer to the lower half of Figure 6 in which a bearing is shown, having cylindrical parts, namely, the cylindrical bolt member A1 and the cylindrical bushing B1, having cooperating cylindrical bearing surfaces. The bolt A1 has a suitable y head M and nut N resting against the outside of the shackle links O and P. Y

The bolt A1 is provided with a longitudinal supply conduit F1 communicating with a cross-passageway G1. formed by a'suitable drilling of the bolt. A circumferential groove Q communicates with the upper end of the cross-drilling' G1 extending completely around the periphery ofthe bolt at the central bearing portion thereof. This groove and the upper end of the cross-drilling G1 communicates with a longitudinal distributing groove H1.

.The bushing B1 yis held in 'a c lindrical sleeve R ,which may be a spring eye ormed on the end of a vehicle spring. The bushing B1 is-preferably formed of brass or bronze and is of a length actually slightly less than the width of the spring eye R, said spring eye forming the spaces between the inside surfaces of the ends of the links O and P. The supply conduit F1 is at its outer end provided with thed-ubricating nipple Z of known type and construction. This lubricating nipple Z has a `ball check valve S and an inlet opening 'I through which lubricant'is adapted tol ing of this kind, since the parts must have suiicient freedom to insure [non-binding action. As a result, the play which is provided inthe bearing ,and which tends to increase with wear is, in cross-section, crescent shaped as may be seen in Figure 7.

Assuming that the play is of the order of .003 inch at the maximum orat the top as shown in Figure 7, it will be fseen that this play `is not suiiiciently large to permit the larger particles of grit, dirt and the like which are found in grease, to be driven from thegend of the distribution groove H the portions I1 and J1 where only the crescent shaped play exists.

In other words, the distribution.l groove H1 l does not extend to the ends .of the bushings B1 and as a consequence the solid portions I1 and J1 constitute portions of the bearing surface and not of the distribution groove. Particles of grit, scale andv other impurities and non-lubricating particles in excess of the size of thev crescent shaped' clearance at its maximum thickness, occur in grease andhence these larger particles are trapped in the distribution groove, particularly at the ends where theyv are filtered out and retained, as ,y

indicated at K2,

Also such particles are trapped and retained in the bottom of the cross-passageway G1 and in the circumferential groove Q.. Finer particles of grit which arecontained in the grease may be driven out of the bearing, if suiiicient pressure is applied, through the centralA or metal part of the crescent duit 226 in the bolt. This conduit communi- J cates with a circumferential groove 228 in the bolt by means of the cross-drill 227.

- A bushing 229 is held in a cylindrical sleeve 230 which may be formed on the en d yof an automobile frame and from which the ve- 95- hicle spring is supported.

.This bushing is pf slightly less axial length Lthan the cylindrical bearing portion 230 and said cylindrical bearing portion 230 may now be clamped fairly closely between the spaces i0 of the shackle lengths O and P in which the grooves 224 are formed.

These grooves extend from the outer spaces formed onthe ends of the links to the hole inl which the bolt 220 is disposed. In other words, the grooves or passageways 224 extend directly tothe bearing surface of the bolt 220. The bushing 229 has one or more longitudinal grooves. 232 and 233 formed therein from end to end of such-bushing 229,

10 these grooves 232 and 233 opening freely at their ends into the passageways 224 which extend radially in the spaces of Ithe shackle links. There is of course the crescent shaped clearance between the bushing and the bearing pin 220, but this now functions in a different manner. Instead of having two grooves, such as 232 and` 233, four grooves,

or any desired number of grooves, more or less than two, may be employed.

The action and inode of operation of this structure may now advantageously be compared with the action of the structure shown immediately below it. The bearing is shown as filled with grease, which has been introduced through the nipple 225. The greasecontains particles of grit of various sizes, some large, some small. They are distributed throughout the body of the lubricant and if they are so large that they cannot escape into the crescent shaped clearance,- tliey are thereby automatically screened out to be retained in the escape grooves 232and 233, as the pin and bearing move with respect to each other,

they do not become lodged in such.cresce`nt the screening action and which were retained in thefree escape grooves, such as 232 and 233, are now forced endwise of such grooves and O ut through the radial passageways 224. to the outside of thebearing away from all bearing surfaces.

The incoming grease may have like inipui-ities and such impurities may again be vsubject to the screening action and to the movement back and forth by the reciprocating or rocking action of the bearing surfaces with respect to each other, tending to concentrate in the grooves and to be expelled1 therefrom upon the next injection .of lubricant. Thisselective action, is in my opinion wholly new in the art. If, for' any cause, the crescent shaped portions shouldtend to have soap or other non-lubricating particles deposited thereinto, it tends to be broken up by motion of the part and be deposited in the free escape groove from vwhich it is thereafter expelled by incoming grease. t

The action of my bearings in tending to screen out particles to keep them from being forced or lodged otherwise between the bearing surfaces, depends upon providing a free passageway for their escape and the provision of such a free passageway of escape is the inherent possibility of the utilization of low pressure. In general, it is desirable where periodic or intermittent lubrication is relied upon, to discharge substantially fixed quantities of lubricant into the bearing. With the high` and excessively high pressure which have heretofore been hoisted upon the art, simple accurate measurement and discharge of a measured quantity of grease or oil into t-lie bearing, by hand or by centralized system, is diiiicult, if not impossible, to attain. Consider, for instance, in Figure 9 where a bearing 235 of my invention is shown and a nipple 23 and gun 238 vof known construction are provided, it has heretofore been difiicult to discharge a fixed or substantially fixed quantity of lubricant by hand operation, where high pressure has been necessary. Finer particles of grit, dirt, soap and the like vwill tend to deposit in the crescent shaped clearance and if as pointed out in connection with the diagrams of Figures 1 to 5 inclusive, such grit is worked back into the distribution groove, it .is merely forced back into the bearing again upon the next injection of lubricant. The finer particles are vtherefore worked back and forth in and out of the distribution groove and tend t be,V packe-il into the horns or smallest part of the crescent shaped clearance, the larger particles being retained in the distribution grooves,

i. longitudinal and circumferential.

Thus gradually there is built up a condition of filling of the bearing with non-lubricating particles and the use of high pressure .or super-pressure to force lubricant into 'the bearing, becomes necessary to get any effective application whatsoever, but even if such high pressure or super-pressure is employed it does not clean out the bearing, for

' 4 as shown in connection with Figure 28 where the clearance is shown y1n exaggerated form,

the lubricant under pressure tends to esc-ape at the ends of the maximum thickness of the crescent shaped clearance and do nothing whatsoever except more firmly pack the non-` lubricating material along the side. The pressure under which the lubricant is introduced has nothing to do with the fundamental laws of aiding the distribution. The

Vlubricant will always seek the path of least resistance, no matter what the pressure is. Thus, in respectto Figure 28, when oil or new grease is forced under high pressure Vto penetrate the frozen portion between the bolt and bushing, it always chooses the very narrow channel indicated at e in the deepest part of the crescent shaped play, leaving the' two center side portions which are filled with soap, grit, metal particles or other non-- lubricating material, as indicated at f, practically undisturbed, and in a short time the bearing is again'frozen.

High pressure lubrication does not force yout all of the old grease, or other detrimental accumulation f, nor does it replace thisl accumulation over any substantial part of the bearing surfaces.

The same thing is true in respect to a bear- 'ing which has only a circumferential groove for distribution of grease, as shown for example in cross-sectional form in Figure 5 3, where there is a cross-drilling G2, commun1- eating with the longitudinal drilling F1, and the circumferential, distribution groove Q. In this case the larger particles K2 which will not pass through the crescent shaped clearance at its maximum depth will be retained in the circumferential. groove Q and just as in the previously described construction, gradually fill up with soap and grit and prevent the entry or distribution of lubricant and if through the use of extremely high pressure, grease is forced through the bearing it will be as described in connectionl with Figure 28, namely, it will escape through the path of least resistance leaving the bearing otherwise in such condition that it will tend shortly to freeze again. l

Referring, now, to Figures and 1l, the

8 at one side of the shackle.

The companion shackle link 9 connects the opposite endsfof the bolts 6 and 7and the 15 nuts 1(), on the threaded ends of the bolt-s. are drawn up to clamp the spring eye 12 and the eye 13 between the links 8 and 9 in thef usual manner. The eye 13 may be the usual perch eye in the axle bracket or brake 'shield go bracket, or any other suitable or equivalent e e. y

In the particular construction shown, these perch eyes 13, at the opposite ends of the front spring, are usually secured to the front axle se an'd at the opposite ends of the rear spring these perch eye members are usually secured to the brake shield in existing practice. This may, however, vary widely. The spring eye 12 has a suitable bushing 14 between the in- 9G ner periphery ofthe eye and the outer periphery of the bolt 7, and the eye 13 has a bushing 15 .between the inner periphery of lthis eye and the outer periphery of the bolt 6. These bushings may be of' cylindrical or tubular 95 form, or they may be split bushings, made up of flat stock rolled toshape, and the bushings of the other embodiments selected for illustration may be similarlyr varied. In fact,

any of the bushings shown herein may be of 10c any existing or any suitable or preferred form, and where the bearing is hushed, as shown,l the present invention may be embodied 'between the bolt and the bushing in a wide range of various manners within the 105 scope of the present invention, as will hereinafter appear. This invention is not, however, limited to bearings employing bushings between the bolt and the eye or female part of the bearing, but the invention may7 be sim- H' ilarly embodied directly between the bolt and eye or other cooperating bearing parts where there is no bushing. l

Near the lefthand side, eachof the Ybolts 6 and 7 has an axial. drilling or duct 16 which 11- leads in from recesses or counterbores 17 formed in the shackle link 8 and opening from the outer side thereof.

At their inner ends, the drillings v16 open into cross ducts or drillings 18, which in 12( turn open out radially into communication with a groove 20.

I desire to point out here that the channel-s or grooves are through channels in that they extend from the cross hole 18 in the 125 bolt or from the cross hole in the bushing or female bearing partit being understood that this cross hole may be in the bushing instead of in the holt or male bearing part, as shown, or it maybe directly in the female 13 bearing part where there is no bushing-to at least one end of the bearing, as distinguished from such longitudinal slots as have been heretofore employed and which have not been through grooves in'` that they have not extended to both ends of the bearing. In the embodiment of Figs. l and 11, the through groove 20, for the bolt 6, is shown as extending to the righthand end of the oearing, whereas the through groove 20 for the bolt 7 is shown as extending to both ends nels may be formed in the eye members '12 and of the bearing. It is to be understood that this is for expediency ofdisclosure and that the through groove arrangement for bothV bolts may be alike or different, or varied, as will hereinafter appear. In the embodiment of F igs. l0 and 11, these through grooves 20 are also shown of longitudinal lineal form, but the grooves of this embodiment, as well as the grooves of the other embodiments, or

rany other applications of the invention, may

are also shown as disposed in the bolts 6 and 7 but it is to be understood that these grooves,

A 0r anyof the other through groove arrange# l and 11, this supplemental escape means,

ments coming within the present invention, may be disposed in the bushing or, where there is no bushing, the female bearing parts, or they may be placed part in the bolt or male bearing part and part inthe bushing' or female bearing part. Where bushings are employed, they may be made of solid tubing or formed of sheet metal rolled to shapeV and' the through grooves may be Aformed by broaching, stamping, pressing, drawing, machining, or otherwise.

In small diameter bearings, I prefer to use not less than two channels, whlle in larger diameter bearings I prefer to use four orI more channels, depending upon the diameter of the bearing.

The throug i grooves are preferably supplemented atthe ends of the bearing by additional free lubricant escape means.l This free lubricant escape means is' particularly desirable where a side thrust is anticipated. The through channel means may extend to one end of the bearing only and, in that case, supplemental escape means at that one end of the bearing alone will sufiice, but preferably, the channels extend to both ends of the bearmg and supplemental escape means is therefore preferably provided atfboth ends of the bcarlng.

In the embodiment illustrated in Figures is in the form. of side channels or grooves 24, these grooves 24 being provided at one end only of the bearing of the eye 13 upon the bolt 6, namely, at the end to which the through channel 20 extends. The through groove 2O for the other bolt 7 extending to both ends of thev bearing, these side channels 24 are shown as provided at each of the opposite ends of the bearing of the bolt 7 in the eye l2. In the illustrated embodiment, these supplemental free lubricant escape channels 24 at the ends of the bearings are formed in the inner surfaces of ,the shackle links 8 and 9 and open across these surfaces from one side to the other, and as also with other bearing channels may be formed by machining, stamping, pressing, broaching, or otherwise.

It is to be understood that these side chan- 13 or, if washers are interposed between the ends of these eye members and the'shackle links, these end` escape channels 24 might be formed in these washers or they may be otherwise disposed to provide additional free lubricant escape means at the ends of the bearings, particularly where a side thrust is anticipated as in the particular embodiment of the Vinvention selected for illustration herein. w A

These end escape channels 24 are disposed in communication with the ends of the ythrough channels 20 and, where there is a relative turning movement, for example, between the eye member and the shackle link, this communication between the through channels and the endchannels is preferably assured t all times by the provision of circular channels 25 (Fig. 11),' which are in continual communication with the ends ofv ply, whereas high pressure lubricant supplies and super-pressure lubricant `supplies only' have 'been -deemed satisfactory heretofore.

`This'substantially resistless bearing and its combination with a source of lubricant sup-` ply, and particularly with a'source of low pressure lubricant supply, is, so, far as I am aware,broadly new', and by these provisions I` greatly improve the lubrication over that obtainedV by bearings of the prior art even when used with high pressure7 or super-pressure systems, all as more fully set out in the'preamble to this specification'.

For the purpose of placing the bearings in communication with the lubricant supply source, I preferably provide each bearing with a lubricant receiving nipple 30.' The particular nipples shown in this application are of the rigidly connected coupling type, that is, they are adapted to provide acoupling connection between the grease gun and the bearing. The inner Iend of the nipple is cylindrical externally, or otherwise formed and of a diameter which will provide a tight driving fit in"the recess 17, in which the nipple is secured by driving engagement therein. v

Each nipple 30 is hollow or tubular providing the internal chamber 32 which opens into communication with the duct or drilling 16 and the outer end ofthe nipple has the reduced or restricted lubricant charging in`- let 34. The outer end of the nipple isenlarged or headed slightly, and this enlarged, l or headedend is externally threaded at 35.

The thread 35`is preferably a relatively short quick thread for quick detachable threaded engagement with the correspondingly interbrication with the present invention the nipnally threaded connector 36 at the end of the lubricant gun (Fig. 25 and Fig. 26). The bearings`being lubricated by low pressure lu ples 30 may be left in open condition when the gun or lubricantsource is disconnected and the spring or otherwise yoperated check valves may thereby be eliminated from the lubricant receiving nipples, although it is to be understood that a conical cork check valve, or other suitable check valve, may be employed, particularly in the case of lubricating a water pump where it ,is desired to prevent the fluid from escaping from the intake opening of the lubricant receiving 'nipple when the gun or lubricant source is discon- The grease'V or oil gun shown inl 25 and 26 forms apart of, and is claime in, a patent issued to Oscar U. Zerk on February 25, 1930, No.f1,748,817, but is illustrative herein of anyv Suitable gun and any suitable lubricant pressure supply and specifically a low pressure ylubricant supply in combination with theimproved .bearing of the present linvention.

This gun comprises a -lubricant container or barrel 40 comprised of, two sections 41 and 42 connected together at 43 as by means of short quick threads which may be pressed in the adjacent `telescoping portions of the barrel sections 41 and 42 because high or super-pressures are not required, and, therefore, true mechanical threads are not necessary between these sections. The. relatively large diameter of the barrel, as compared with its length enables a very material re- :cured in any suitable manner in the opening 49 is a bushing 51 which is internally thread'- ed at 52 for threaded engagement with the threaded shank 53 of thel piston stem, the upper end of which is bent to form or otherwise provided with a suitable handle'r 54. An abutment formed by an embracing'ring 55 secured in a circular groove 56 in the piston stem forms a stop for engaging the pperend of' the bushing 52 to 4limit the downward movement of the piston 58. pointed out, the lubricant barrel of the gun is of relatively large diameter and relatively short length. Itslength is preferably less than its diameter;

Thelpiston or plunger 58 is composed of two -dished or generally spherical relatively thin piston ldiscs 60'and 61 secured centrally to the lower end ofthe 'piston stem 53 as b passing a reduced portion 62 thereof throug As already the discs 60 and 61 and heading or riveting' over the lower end of this reduced portion at Marginally a self-sealing. gasket v65- preferably of leather or other suitable material is suitably secured at 66 between the outer margins of the discs 60 and 61, and the outer edge of this self-sealing gasket is turned down at 67 and has seahng cooperation with the inner periphery of the` barrel of the gun. The gasket 65 may have a relatively large central opening 68 eliminating weight andk expense and making the gasket in the form Iof an-annulus.

To receive the inner `margin of the gasket between thedi-scs and to facilitate securing of the same there, the outer margin of the lower disc 6,1'may be oiset as shown at 69. Nozzle 47 has its upper end formed outwardly as shown at 48 and engages in a suitably formed opening 46 in barrel portion'42 of as shown by a simple stamping operation', and when assembled may be spot welded atl 45 to provide a rigid connection therebetween.

The connector 36 at thelower end of the nozzle 47 comprises a fitting having a reduced upper end 72 threaded at'73 into the lower' end of the nozzle 47. This fitting has a reduced orrelativelv restricted discharge opening 74 axially thereof and ada ted tol openfrom the nozzle 47. The body o the fitthe gun. r Both of these partsvmay befformed ting is counterbored at 75 to receive a ball check valve 76 and a spring 77 for seating the valve 76 upwardly to its seat around the opening, 74. Below the counterbore 75 the body of the fitting has a second counterboreV 78 in which. a bushing 79 is secured'as by a pressed 'fit. The bushin 79 contines the spring 77 and securedn' t e counterbore 78 beneath this bushing 79 is a felt or other suitable yielding washer 8O which is adapted to abut the outer end ofthe lubricant receiving nipple when the quick detachable threaded connection is effected between the threads 35 thereof and the internal threads 82 in the counterbore 78 beneath the washer 80. The

" bushing 79 and washer 80 have relatively restricted registering apertures 83 through ywhich' thelubricant is discharged from the nozzle 47 and into the fittingl 30 or such other fitting as may be provided atthe bearing. In addition, the bushing 79 is counterbored upwardly to complete the chamber for the spring 77. The enlarged lower end of the might be provided at the outlet of the gun,

fitting 36 forms a shoulderwhich abutsthe lower end ofthe nozzle 47 at 85 and the outer periphery of the enlarged lower end is preferably knurled, as shown in Fig. 26, to facilitate quick detachable threaded engagement with 4the bearing nipple. y Of course, any othersuitable check valve ing with relatively little pressure, because' of the removal of most of the resistance to the incoming lubricant at the bearing. Lu-

` brication is not only obtained with from 10 to pounds pressure per square inch instead of from 300 to 10,000 pounds per square inch with the advantages already referred to, but the lubrication of the bearing under this low pressure is improved over what has been considered as acceptable lubricatibn under high and super-pressures, as already ex-V plained.

In the embodiment of Figs. 16 and 17, the' through channels, instead of being continuous to the opposite ends of the bearing, are formed by channels 90 leading from the cross openings 93 tol one end of the bea-ring, and.

channels 92 leading from cross-openings 93 to the opposite end of the bearing. Each of f the channels 90 and 92 is a through channel -from its cross opening to one end of the bearing, and these channels supplement each other and form, in effect, continuous through channels to both ends of the bearing.

These channels are again shown in the bolt I 94, but it is to be understood that, as before, they may be in the bushing 95 or directly in the female bearing part 96 or part may be in the bolt and part in the bushing or female bearing part. The -shackle'links are indicated at 8a and 9a, and one end of the bolt *is headed at 97 while the opposite end is provided with a nut 98. The free lubricant escape end channels are designated at 14a.

'In Figs. 18 and 19, the through groove or channel is in the form of a helical groove 100 again formed in the' bolt 101, although it may Y be 'formed in the bushing 102 orin the female bearing part, in which case, where the cross opening 104 is in the bolt, it may communicate with a helical channel in the bushing or in the female bearing part by means of a circular groove formed around the bolt 101 and intersecting the outer end of the cross opening 104. p

i In the embodiment of Figs. 20 and 21, some of the through channels 110 are formed in the bolt 111, while others are formed in thebushingl as indicated at 112, althoughthey may be Jformed directly in the female bearing 113 where there is no bushing. A bushing is shown at 114. Cross ducts 115 open into communication with the through channels 112 and into Comunication with an annular groove 116 in the bolt 111, which annular groove 116 in turn communicates continually f with the through channels 110.

l In the embodiment of Figs. 12,13, 14 and ,15, the through channels 120 are similar to the through channels `20 or the bolt 7 of Fig. 10, with the4 exception that theyare formed in the bushings 121 instead of in the bolts or male bearing parts 122.

The cross ducts 123 open radially through the bolts 122 into communication with annular grooves 124 formed peripherally around the bolts and intersecting the outer ends of the cross ducts 123. The annular grooves 124 maintain continuous communication betweenl the cross duct 123 and the through channels 120. The bushing 121, shown around thel upper bolt 122, is a split bushing, split at 126. It may be formed of flat stock rolled to shape, as already referred to. The throughgrooves 120 may be formed by broaching, stamping, pressing, machining, drawing or otherwise, as previously explained.

In Figs. 12 and 13, the shackle links are indicated at 8b land 9b, but the bolts 122, instead of being formed integral with one link at one end, as in the embodiment of Figs. 10 and 11, pass through the link 8a and are headed at 130. The heads 130 are formed at 131 to receive a wrench or other tool and in this case the nipples are press fitted'in recesses 17' in the heads 130 instead of directly in one of the shackle links. The free lubricant escape end grooves in the inner surfaces of the shackle links are indicatedat 132 in Fig. 13, and annular grooves are indicated at 133 for maintaining these vfree escape end grooves 132 in communication with the through grooves 121.- The anchoring eyeis lindicated at 135. and the spring eye at 136 in Figs. 12, 14 and 15.

The bearing illustrated in Figs. 22, 23 and 24 is the shackle bearing of another form of standard type for use on automobiles.

yThe shackle bolt 150 is the upper shackle bolt and is supported in a bearingmember 151 formed on a bracket 152 which is usually secured to the frame member. The Lbolt 150 A is held definitely in position by the slabbedequally spaced longitudinal through chane nels 162 are provided in the inner surface of the bushing 160 and extend from none end of the bearing to the opposite end. The axial duct, into the outer end of which the lubricant is delivered into'the shackle bolt, is indicated at 163 and this duct opens through cross ducts 161 to a circular duct 165 encircling the bolt 150 and intersecting the outer ends` of the cross ducts 164. `The circular `groove 165l opens continually into the through channels 162 regardless of turning movement between the bolt 150 and the bearing part 151. The free lubricant escape end channels are provided at one end at 168 in the inner surface y ot the washer-158 and' atthe opposite end these channels 17 O'are provided in the inner surface of the shacklelink 156. rAn annular groove 172 in the inner surface of the Washer 158 maintains the through channels 162 in open communication with the free escape end channels 168, regardless of relative turning movement between the washer and the bearing part 151 and a similar annular groove 174 in the inner surface of the shackle link 156 maintains the end channels 170 in free communication with the through channels 162 regardless ofrelative turning movement between these parts. l i

In the embodiment ofFi'gs. 22, 23 and 24, the lubricant charging nipple 180 is connected with and-opens into the axial duct 163 and, instead of having driving'it, is threaded directly into the bolt 150 atf 182. In this caSe,

the nipple 180, instead of being open when the lubricant source is disconnected therefrom, is closed by a conical cork check valve 185 cooperating with the correspondingly tapered or conical bore 186 at the outer end of the nipple 180. The.cork check valve is preferable, Vbut this may vary. This valve is seated by a spring 188 confined at its inner end by an annular flange 190 at the inner end of the nipple 180. Obviously, the nipple 180 of this embodiment may be used in connection with any of the other embodiments, lor the other nipple may be used in this embodiment,

or the nipples may be varied from the particular structures shown, as, for example, in providing a pressed contact instead of a rigidmechanical connection. The outer end of the nipple 180 is provided with a relatively shortfquick thread ,192 for connection with the grease gun.

In Fig. 27, I have shown an angle or elbow nipple for use in connection with the lpresent invention. Y This nipple comprises a nipple part 200 threaded at 201 for threaded engagement with the boltor bearing part and a tubillar nipple part 202 having driving fit in the part 200 and disposed normally thereto. f 'Ihe inner chamber or duct of the part 202 .is 1n open communication with the chamber 204 of the part 200, 4the interior of the part 200 being recessed at 205 to promote this communication. The inlet or receiving opening 206 of this nipple is normally closed by a ball check valve 207 seated against the struckin margin or flange 208 at the inlet 206 by a spring 209 which is con'ned at its opposite end by. an internal annular flange 210 within cthe nipple part 202. The inlet end of the` part 202 is externally threaded at 215 for quick threaded connection with the-cooperating connector of the grease gun.

NOW referringI again to Figure 6, and Aparticularly the upper shackle bearings, I show herein a shackle'bolt 220 with a head 222 and nut 223 holding the same in the upper ends ofthe shackle links O and P. -The iny ner faces of these shackle links are provided with` radially extending passageways 224 facing toward each other. The head 222 receives a lubricating nipple 225 which is constructed as disclosed andclaimed in my copending application `filed September 28, 1929, 'and bearing Serial No. 395,878. The bolt 220 has a longitudinal drilling 226 and the vertical vcross-drilling 227, this cross drilling communicatingwit-h a. circumferential distribution groove 228 which has the same general function as the distribution groove Q, disclosed in the structure immediately below it. l

The bushing 229 which is disposed in the cylindrical sleeve 230 forming a part of the frame horn or the like, bears upon the cylindrical surface of the blt.

For example, if the bearings were relatively free, one turn of the handle 239 might discharge sutlicient grease to lubricate the bearings. If, on the other hand, the bearings were thoroughly well clogged up, that is filled [up with non-lubricating particles, the operatimes to reduce the pressure in the gun bar-v rel to such an extent as to enable him to unhook or unscrew the coupling between nozzle and nipple. 'Ihis has been due largely to have prevented accurate measurement, due

` to the expansion of such air after being placed under pressure, next'due to the leakage incident tothe use of high pressure, next due -to the diliiculty of determining in the mind of the operator or securing in factany definite relation between a predetermined angular movement of the handle 239 and adenite discharge of grease into the bearing. The nsame thing is true in respect to the` contact type where the necessity yfor high pressure has tended to cause leakage and even though a definite predetermined stroke of the gun were made, there was noassurance of securing the discharge of`a desired amount of lubricantinto the bearings.

Now consider the possibilities of my present bearings, as shown in Figure 9. In the .upper bearing 235 provided with the solid coupling type of nipple 237 and screw thread operated type of discharged gun 238, due to the free escape channels which the bearing 235 embodies, av definite turn of the handle 239 results in the deinite discharge of a predetermined quantity of lubricant into the bearings. Upon uncoupling the gun the grease does not tend to leak out of the gun, as has heretofore beenV the case.

The bearing 235 is shown as having sub stantially the vconstruction described in detail inv Figure 6. 5

The bearing 236 is like' the bearing 235 and it is provided with a contact type of nipple .242. The gun 240 is provided with a contact nozzle 243. 4The gun 2l() is further provided with a spring 244 making a detinite'return stroke of the plunger, so that each operation of the gun will automatically provide a. predetermined discharge. v Due to the elimination of resistance in the bearing, the discharge of a definite quantity ofgi'ease is greatly facilitated as above described. The same thing is true in a centralized lubricating system. The present form of bearing has a great advantage, first in providing a better bearing and next in permitting the resistance of the 4 resistance typemetering unitsto be relatively lowand yet 4many times higher than there' sistance of the bearings. Consequently, the distribution of lubricant throughout the system may be much more easily accomplished where a centralized system is employed.

By the term heavy lubricant employed herein I mean to include high viscosity oil,

" grease or the like.

Obviously I do not intend to be limited tp the vdetails of construction, except as they are specifically recitedfin the claims, since I conceive the method of opera-tionand the structure herein disclosed to be broadly new.

I claim:

1. In combination two bearing members having cooperating bearing surfaces with a duct leading to the bearing'surfaces and a substantially free escape passageway communicating withthe duct to receive lubricant therefrom and communicating laterally with the bearing surfaces to deliver lubricant thereto and substantially freely opening longitudinally outside of the bearing surfaces for the ejection of impurities away from the bearing surfaces.

2. In combination two bearing members having cooperating bearing surfaces with a duct leading to the bearing surfaces and a substantially free escape passageway communicating laterally with the bearing surfaces to deliver lubricant thereto and freely opening longitudinally outside of the bearing surfaces for the ejection of impurities away from the bearing surfaces, said bearing members being organized to have oscillatory motion with respect to each other and detachable means for intermittently discharging a yhigh viscosity lubricant into the duct.

3. In combination two bearing members having cylindrical bearing surfaces with the duct leading to the said bearing surfaces and having radially extending bearing surfaces at the ends of the cylindrical bearing surfaces, there being a substantially free escape passageway extending from the duct longitudinally along the cylindrical bearing surfaces and communicating laterally with them, there being a radially extending substantially free escape passageway along one of said radially extending bearing surfaces, and there being a circumferential passageway providing substantially free communication from the substantially free escape passagewaylof the cylindrical portion of the substantially free escape passageway of the radially extending portion.

4. A bearing comprising the combination of two relatively movable members, having cooperating bearing surfaces adapted to be separated by a lm of lubricant, there being a supply duct for lubricant extending to the meeting surfaces, one of themembers having a -groove extending from said duct to the limits of the bearing surfaces and opening substantially freely away from the bearing surfaces for the discharge of previously deposited lubricant by the introduction of a fresh charge of lubricant through said duct and groove. v

5. A bearing comprising the combination -of two relatively movable members, having eating particles fr om between the bearing surfaces. second, to provide al passageway throughwhich the deposited non-lubricating i particles may be swept away by the injection of fresh lubricant and third, to actas a storage reservoir for lubricant between injections of fresh lubricant.

6. A bearing adapted for intermittent lubrication by application of a heavy lubricant comprising the combination of two bearing members having cooperating bearing surfaces, at least one of said members havingva groove at its bearing surface covered by the other bearing member, there being an inlet passageway for lubricant communicating' with said groove and a grlt escape passagemotion of their surfaces with respect to each other.

7. In a lubricating system of the intermittent, non-circulatory type the combination of bearing s. members having bearing surfaces adapted to be lubricated by heavy lubricant, said bearing members/having a supply duct and having a groove extending between said members opening laterally to said bearing surfaces .and serving kas a reservoir for lubricant for supplying said surfaces between.

operations of lubricant injections, said groove having a free escape opening outside of said surfaces to carry away substantially freely impurities from the bearings and an inlet connection for said supply duct, having closure means for preventing the entry of impurities between operations of lubricant'injections.

8; In a lubricating system of the intermittent, non-circulatory type the combination of bearing members having bearing surfaces adapted to be lubricated by heavy lubricant, said bearing members having a supply duct and having a groove extending between said membersopening laterally to said bearing surfaces and serving as a reservoir for lubricant for supplying said surfaces between operations of lubricant injections, said groove having a substantially free escape opening outside of said surfaces to carry away substantially freely impurities from the bearings and an inlet connection for said supply duct, having'closure means for substantially preventing the entry of impurities between operations of lubricant injections,.and lubricant supply means adapted to be put into communication periodically with said inlet connection for discharging fresh charges of lu.-

bricant into the groove.

9. In combination with a vehicle spring, a pair of cooperative bearingelements for said spring having interengaging substantially co-axial bearing surfaces, one of said ele- -ments having a lubricant charging duet formed therein adapted to convey lubricant supplied to it under pressure to said surfaces, the bearing surface of at least one of the elements being so grooved as to form a channel lfreely communicating with said duct, and

with atmosphere, to conduct without appreciable resistance lubricant from the duct and impurities selectively retained by the filtering action of the channelY to atmosphere longitudinally of said bearing surfaces and in contact with both thereof.

ll0. In a bearing substantially as defined in claim 9 in combination with means forming discharge channels extending angularly ouowardly from the said first named channe y 11. In a 'bearing substantially as defined in claim 9 in combination with a pair of shackle links one of said ele-ments supported by the shackle links, the other element interposed therebetween.

l2. In a bearing substantially as defined in claim 9 in combination with a pair of shackle links one of said elements supported by the shackle links, the other element interposed therebetween and means forming discharge channels extending outwardly from the said first named channel.

13. In a bearing substantially as defined ment having the`duct and communicating directly with Vsaid duct, said duct comprising 'a bore of said element, said nipple adapted for lubricant communicating engagement by a lubricant gun nozzle applied thereto, the said bored element being annularly grooved intermediate its ends, said element bore terminating at its inner end in free Communication with the annular groove.

14. In a bearing substantially as defined in claim 9 wherein the bearing surface channel groove extends from` end to end of the bearing and communicates with atmosphere at at least one of its ends.

15. In a bearing substantially as defined in claim 9 lwherein a second channel forming a longitudinally extendingl groove is provided in at least one of said elements, spaced throughout at least most of its length from the first named groove and providing a multiple passage for lubricant from the duct to atlnosphere.

16. In a' bearing substantially as defined in claim 9 in combination with means forming discharge channels extending angularly outwardly from the said first named channel at the ends of said bearing and means forming an annular channel intersecting both said first named and the second named channel.

17. In combination, two bearing members having bearing surfaces adapted for relalSO provided with a lubricant supply duct lead-y lng to said surfaces at substantially the cen` ter thereof, and one of said surfaces being provided with a groove communicating with `said duct and extending the full length of said bearing surface, the ends of said groove Ibeing open to the atmosphere to provide a vent through which the impure lubricant may be discharged upon supplying lubricant to said bearing through said duct.

In witness whereof, I hereunto subscribe my naine this 5 day of October, 1929.

` oscAR. U. ZERK 

